Sulfosuccinates of polyhydroxy tertiary amines

ABSTRACT

wherein R1 is a monovalent hydrocarbon radical of eight to 24, preferably 10 to 20 carbon atoms; R2 is an alkyl or alkylol radical containing one to six carbon atoms, and R3 is an alkylol radical containing one to six carbon atoms, and salts thereof. The reaction mixture consists of sulfonated mono-, di-, and/or tri-esters, depending on the number of reactive hydroxyl groups in the alcoholamine and the amount of dicarboxylic acid utilized. These novel esters and salts thereof uniquely possess both detergency and softening properties. Novel sulfosuccinates of 2-hydroxy alkyl tertiary alcohol amines having the structural formula:

llnited States Patent [1 1 Sundby Dec. 23, 1975 SULFOSUCCINATES OF POLYHYDROXY TERTIARY AMINES [75] Inventor: Bjorn Sundby, Piscataway, NJ.

[73] Assignee: Colgate-Palmolive Company, New

York, NY.

[22] Filed: Dec. 6, 1971 [21] Appl. No.: 205,395

[52] US. Cl 260/481 R; 252/354; 252/526;

260/485 .1; 260/50l.l; 260/501.l7; 260/584 R [51] Int. Cl. C07C 143/12 [58] Field of Search 260/481 R; 252/354, 526

[56] References Cited UNITED STATES PATENTS 2,176,423 10/1939 Jaeger 260/481 2,844,608 7/1958 Hagge et a1. 260/481 R 3,002,995 10/1961 Williams 260/481 3,349,122 10/1967 Segessemann 260/513 B Primary ExaminerJohn F. Terapane Attorney, Agent, or FirmSteven J. Baron; Norman Blurnenkopf; Herbert S. Sylvester [57] ABSTRACT Novel sulfosuccinates of 2-hydroxy alkyl tertiary alcohol amines having the structural formula:

3 Claims, No Drawings SULFOSUCCINATES OF POLYHYDROXY TERTIARY AMINES This invention relates to novel sulfosuccinates of Z-hydroxy alkyl tertiary alcohol-amines and salts thereof. It has been discovered that said compounds are useful surface active agents and are substantive to a variety of fibrous materials. Thus, they may be used as emulsifiers, solubilizing agents for lipophilic materials, wetting agents, detergents and softeners for textiles and hair.

Since the introduction of commercial synthetic organic detergents and emulsifiers to replace the conventional watersoluble higher fatty acid soaps, much research work has been performed in an effort to improved such compounds and compositions including them, with the object of obtaining better and more convenient laundering of textiles. As a result, a wide variety of types of surface active agents and detergents have been produced and many such compositions have been manufactured commercially and have been introduced to the market place. As better products were made, the goals set for researchers on detergency were increased and the properties of the desired products were such as to have been thought impossible of attainment only a few years before. Although the cleaning function of surface active materials is still very important and products which clean better than competitive compounds are always in demand, additional attributes of cleaning compounds were desired. For example, with the increasing importance of cold water washing, detergent compositions were desired which would be capable of successfully cleaning and whitening textiles and laundry in cold water, as well as in hot water. Such washing capability is of importance in making a product acceptable for the washing of wool and other shrink-sensitive materials. In addition, softening agents have been found to be a desirable and, in some instances, a necessary ingredient in the washing of textiles. However, because of the incompatibility of softeners and detergents, it has been necessary to utilize the textile softener in the final rinse as a separate step in a washing cycle. The objections to this procedure are obvious; one must be present during the washing cycle and few washing machines include devices for the addition of softeners in the final rinse.

Therefore, it has been the long desire of the detergent industry to provide a single compound possessing the foaming and detergency characteristics of conventional detergents, yet uniquely possessing fabric softening ability. Such a single compound uniquely possessing both detergency and fabric softening ability would, of course, eliminate the disadvantages of employing two separate materials, and, in addition, would completely eliminate the disadvantages associated with the incompatibility of conventional anionic detergents and cationic fabric softeners.

The sulfonated esters of instant invention possess detergency, wetting, foaming, and emulsifying properties in both hard and soft waters and at both elevated and lower temperatures. In addition, these compounds exhibit substantivity to materials such as cotton, hair, etc. and are excellent in textile softening activity. This high degree of substantivity is unexpected in a surface active material which itself functions to release adsorbed and absorbed substances from materials being washed. Consequently, instant surface active agents simultaneously clean and soften textiles.

0 ll ll which are effective detergents and which also serve to soften fibrous materials when applied to them, as in aqueous solution. In the formula, R is a monovalent hydrocarbon radical of eight to 24 and preferably to carbon atoms, R is an alkyl or alkylol radical of one to six carbon atoms, R is a divalent hydrocarbon radical of one to six carbon atoms (R OH=R R is a divalent hydrocarbon radical (residue of the sulfonated dicarboxylic acid); X is hydrogen or a salt-forming element or radical. If X is an element, it is preferred that it should be an alkali metal such as potassium,

sodium and lithium or other suitable salt-forming metal. If X is a radical, it is preferred that such be ammonium, alkylamine or alkanolamine, eithe'r mono-, di-, or tri-alkylamine or mono-, dior tri-alkanolamine, in which the alkyl and alkanol groups of the salt-forming amines are of one to four carbon atoms, preferably 2 to 3 carbon atoms.

The novel sulfonated esters of the present invention can be prepared by a two-step synthesis comprising the esterification of the polyhydroxy tertiary amine with an unsaturated dicarboxylic acid and subsequently sulfonating the ester with an alkali metal sulfite salt or by other suitable sulfonating means. More specifically, the ester may be formed by reacting the unsaturated dicarboxylic acid or preferably the anhydride thereof with a polyhydroxy tertiary amine having the structure:

wherein R is a monovalent hydrocarbon radical of eight to 24 and preferably 10 to 20 carbon atoms, R is an alkyl or hydroxyalkyl radical containing one to six carbon atoms, R is a hydroxy alkyl radical containing one to six carbon atoms. Examples of radicals of this class are:

4 and related compounds in which the radicals contain The reaction is predominantly in accordance with the more carbon atoms than in the formula shown above, f ll i tions;

on R R 2. R CHCH N-R OH+ C on R OH R 0 I 2 3 lg RI H2- 4 R5 OOH, R CHCH NR 0 --R COOX SO;,X

e g adi al f di(i o o ol)a i N- th l-N i wherein the R radicals are as aforedefined and equimopropanol-amine, N-ethyl-ethanolamine, N-ethyl-N-isolar amounts of reactants are used. The sulfonation step propanolamine, N-propyl-N-ethanol-amine, N-propyll5 adds the sulfonate group to the unsaturated acid radical N-isopropanolamine, N-methyl-N-hydroxyethoxyethylat the point of unsaturation as illustrated by the followamine, N-butyl-N-hydroxy-ethoxyethylamine, N- ing equations when utilizing maleic anhydride:

OH R2 0 OH R2 Na SO I ll R1CHCH2N-R4OCCH=CHCOOH CHCH -NR.,oC (pH CH C00Na SO Na cyclohexyl-N-hydroxyethoxyethylamine, N-butyl-N- The alcoholamine has at least two hydroxyl groups, one ethanolamine, di(hydroxyethoxyethyl)amine, mono(- in the long chain resulting from the epoxide ring open- 3O hydroxyethoxyethyl)amme, N-hydroxyethoxy-ethoxmg and one or more from the original alcoholamine. yethyl- N-hydroxyethyl-N-hydr0xy-is0pr pylamine, When utilizing equimolar amounts of reactants, the N-benzyl-N-hydroxyethylamine, or N-cyclo-hexyl-N-Z- primary hydroxyl is preferentially esterified into the hydroxy-Z-phenylethylamine. mono-ester, since it is the least stearically hindered and therefore the most reactive group. However, when The polyhydroxy tertiary amines are known commore than one mole of the acid anhydride is used, the pounds which may be prepared by condensing secondother hydroxyl radicals react to form the di-ester, triary alcoholamines with long chain epoxides. A typical ester, etc. and mixtures thereof. Similarly, the number example of an amine/epoxide reaction is the preparaof hydroxyl groups in the alcoholamine is determination of Z-hydroxyalkyl-diethanolamine. 4O tive of the formation of the mono-, di-, or tri-esters.

Ol-l /CH2CH2OH /Cl-l CH Ol-l heat 1. R -CHCH HN R1 2 ca c HQOH cn crnon (\)H CH2CH2OH COOH |CHCH2N 11 mono-, di-, and

\ tri-esters CHZCHZOH COOH ?H CH CH OH COOH R1CH-CH2N R5/ c m0no-,di-esters CH3 COOH OH zlilkyl COOH 6. R,CH-CH N CH,CH oCH CH 0H R monoand diesters COOH di-esters The unsaturated dicarboxylic acid anhydride may be The sulfonated esters formed in accordance with maleic anhydride or a substituted maleic anhydride. instant invention have one free carboxyl group and one Q sulfonate group for every esterified carboxyl radical as' E R shown by the following structural formulae:

Mono-ester: /R l d R5 R l c R RICH-CHQ-II\IR4OOCR5COOX ll 0 2 so x Di-ester:

Tri-ester:

SO X

OOCR COOX SO X The esterification of the 2-hydroxyalkylalcoholamines with the unsaturated dicarboxylic acid anhydride is an exothermic reaction which can be carried out in aprotic solvent, ether, chloroform or acetone, but it can also be carried out neat. The latter method is preferable as an industrial process, since no solvent is involved, thereby not giving any by-products. The powdered acid anh'ydride (e.g., maleic anhydride) is added gradually to the liquid alcoholamine which is held at a temperature of about 100C. When the reaction is over, the product is cooled and subsequently sulfonated by the addition of the ester to an aqueous solution of a sulfite salt. The mixture is heated to about 50-90C with agitation, for a period of about 30-60 minutes. A clear, viscous solution is obtained. The final product may be freeze dried and is obtained in the form of a solid, which is insoluble in acetone, ether, etc., but very soluble in water. When utilizing a solvent during the esterification step, the reactants are first dissolved therein and the solution refluxed until the reaction is complete. Evaporation of the solvent yields a resin-like, waxy product, insoluble in water, which is subsequently sulfonated as above. When utilizing the unsaturated dicarboxylic acid in lieu of the anhydride, esterification is controlled so that only one mole of water is removed per mole of alcohol. Termination of esterification at this point ensures the formation of mono-, di-, and/or tri-esters and prevents the production of a polymeric linear ester. The esterification may be controlled by conventional methods of cooling or by other suitable means.

The products obtained are usually clear, viscous solutions of sulfonated mono-, di-, tri-esters and mixtures thereof, readily soluble in water. The sulfonated monodiand tri-esters can be readily separated and purified by chromatographic techniques in the usual manner. However, separation is not necessary. The mixture of mono, di-, and/or tri-esters can be used as the effective detergent, due to their combined property of detergency and fabric conditioning (softening, anti-static, etc.). The high viscosity solutions that some members of this series form render them particularly useful in shampoos.

Examples of sulfonated esters in accordance with the present invention include:

Sulfosuccinate of N-(Z-hydroxy hexadecyl) diethanolamine Sulfosuccinate of N-(Z-hydroxy octadecyl) diethanolamine Sulfosuccinate of N-(Z-hydroxy octadecyl) diisopropanol-amine Sulfosuccinate of N-(Z-hydroxy octadecyl) diglycolamine Sulfosuccinate of N-(Z-hydroxy octadecyl) methylethanolamine Sulfosuccinate of N-(Z-hydroxy dodecyl) diethanolamine sulfosuccinate of N-(Z-hydroxy dodecyldiisopropanolamine Sulfosuccinate of N-(2-hydroxy dodecyl) diglycolamine Sulfosuccinate of N-(2-hydroxy dodecyl) methylethanolamine Sulfosuccinate of N-(Z-hydroxy tetradecyl) diethanolamine.

The novel sulfonated esters of the present invention, in addition to possessing excellent detergency and fabric softening properties, have been found to be compatible with the various detergent builders and other additives conventionally employed in detergent compositions. Accordingly, it is possible to formulate a detergent composition based upon the sulfonated esters of instant invention as the sole detergent and fabric softener.

Various embodiments of the present invention will now be illustrated by reference to the following specific examples. It is to be understood, however, that such examples are presented for purposes of illustration only and the present invention is in no way to be deemed as limited thereby.

EXAMPLE 1 Preparation of disodium sulfosuccinate of N (2- hydroxyhexadecyl) diethanolamine:

TABLE I ARd (Soil Removal) 70F 120F Compound NB-TAP 300 PPM NB-TAP 300 PPM 1. Disodium sulfosuccinate of N'(2-hydroxyhexadecyl) diethanolamine 12.3 1 1.2 17.6 12.5 2. Control-Linear tridecyl benzene sulfonate 16.2 9.9 21.0 12.2 3. Disodium sulfosuccinate of N-(2-OHC,,,) diethanolamine 12.8 10.2 17.1 13.5 4. Disodium sulfosuccinate of N-(2-OHC methyl ethanolamine 14.3 10.9 13.6 13.0 5. Disodium sulfosuccinate of N(2-OHC diisopropanolamine 14.4 11.2 13.9 16.3

10 gms. maleic anhydride was stirred into a hot melt (100C) of 35 gm. 2-hydroxyhexadecyldiethanolamine. The mixture became rapidly very viscous. After 10 minutes, it was cooled and added to 12 gms. sodium sulfite in 100 ml water. The mixture was heated to 90C with stirring. After one hour, a clear viscous solution was obtained. The product was freeze dried, yielding a solid, which is insoluble in acetone, ether, etc., but very soluble in water. This sulfosuccinate produces a very dense foam in aqueous solution.

EXAMPLE 2 Preparation of disodium sulfosuccinate of N-(2- hydroxy octadecyl) methylethanolamine:

CH SO Na This product is prepared as in Example 1.

EXAMPLE 3 Preparation of disodium sulfosuccinate of N-(2- hydroxy octadecyl) diisopropanolamine:

This product is prepared as in Example 1.

The instant novel sulfonated esters and salts thereof were tested for their detergency properties as well as their efficacy as fabric softeners. The Spangler soil detergency tests were run using an aqueous solution containing 1.5 g. of detergent/liter water (0.15% product concentration) said detergent comprising 15% of the compound to be tested, 35% sodium tripolyphosphate and 50% sodium sulfate (based on dry ingredients), in soft and hard water, at both 70F and 120 F. Three Spangler soil swatches were washed 10 minutes in a Tergotometer at 100 rpm, rinsed 5 minutes, and dried. The ingredients were dry-blended by conventional methods and added to the aqueous system in the Tergotometer.

TABLE II Softness Ratings 1. 10 g Al sulfosuccinate of N-(Z'hydrox hexadecyl) diethanolamine, 40g Pentaso ium Tripol phosphate (NaTPP) 7 2. 10 o sulfosuccinate of N-(Z-hydroxy octadecyl) methylethanolamine 40% NaTPP l0 3. 10% sulfosuccinate of N-(Z-hydroxy octadecyl) diisopropanolamine 40% NaTPP l0 4. 5g Al sodium sulfosuccinate in (1),

10g Al linear dodecyl benzene sulfonate,

40 g NaTPP 5 5. 30g sulfosuccinate 0f N-(Z-hydroxy octadecyl) diethanolamine 6. Linear tridecyl benzene sulfonate l The results shown above indicate an unexpectedly excellent detergency in hard and soft water, both cold and hot, as compared to commercial detergent linear tridecyl benzene sulfonate. In addition to possessing excellent detersive properties, instant sulfonated esters exhibit excellent fabric softening characteristics, not possessed by the control. Similar results are obtained with other sulfonated esters of 2-hydroxy alkyl tertiary alcohol-amines.

The present invention has been described in conjunction with various illustrations and embodiments thereof set forth in the specification. However, it is evident that equivalents may be substituted for the present compounds and procedural steps, without departing from the principles of this invention or the spirit thereof. Those of skill in the art will recognize what equivalents and substitutes are also within the scope of the present disclosure.

What is claimed:

1. Disodium sulfosuccinate of N-(Z-hydroxy-hexadecyl) diethanolamine.

2. Disodium sulfosuccinate of N-(Z-hydroxyoctadecyl) methyl ethanolamine.

3. Disodium sulfosuccinate of N-(2-hydroxy octadecyl) diisopropauolamine. 

1. DISODIUM SULFOSUCCINATE OF N-(2-HYDROXY-HEXADECYL) DIETHANOLAMINE.
 2. Disodium sulfosuccinate of N-(2-hydroxyoctadecyl) methyl ethanolamine.
 3. Disodium sulfosuccinate of N-(2-hydroxy octadecyl) diisopropauolamine. 